Method of determining range

ABSTRACT

A method of determining range between two objects, where a grid consisting of a plurality of grid lines are projected into space by the first object and detected by the second object.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. patent application Ser. No. 12/644,727 and a continuation-in-part of U.S. patent application Ser. No. 12/644,743 both of which were filed Dec. 22, 2009, and are incorporated herein by reference.

BACKGROUND OF THE INVENTION

This invention relates generally to the field of relative navigation systems and methods of relative navigation.

Relative navigation systems are useful for various applications such as autonomous vehicle navigation, mid-air refueling, and space docking. In some applications, only the range between two objects is required. In other applications, both the range and the relative attitude (pitch, yaw, and roll) between two objects are required. Such information is typically gathered as a time series and used to make course corrections in one or more of the objects to enable a desired maneuver or final relative position.

Some applications benefit from a minimal form factor and weight, as well as, highly reliable operation often in harsh environments of a relative navigation system.

Capture and servicing a space satellite is an example of an application where a relative navigation system can be used. In such application, both the range and the attitude measurements between the target satellite and the chase vehicle are required to allow proper orientation during capture. Additionally, this application is in an extreme environment and excess weight and volume of the satellite or chase vehicle can add to the cost of such operations.

Another application may be autonomous vehicle navigation in a warehouse or factory environment. In such an application high reliability and low cost are desirable.

BRIEF DESCRIPTION OF THE INVENTION

In one embodiment, a method of determining range between first and second objects with relative movement, where a plurality of grid lines from a first origin point on the first object are projected into space. Each of the grid lines are modulated to carry a grid word comprised of a number of modulated bits to identify each grid line within the grid by the modulated grid word. The grid lines and the corresponding grid words are detected from at least three locations having a predetermined triangular relationship on the second object, with each location defining a vertex of the triangle, with three unique pairs of vertices. The location within the grid of the three vertices is determined based on the grid word detected at each of the at least three locations and for each unique pair of vertices. An angle subtended by a pair of unit vectors extending from the origin is based on the location within the grid of each of the vertices, where each unit vector passes through one of the vertices of the unique pair to form a set of three subtended angles. The range between the first and second objects is determined based on the set of subtended angles.

BRIEF DESCRIPTION OF THE DRAWING

In the drawings:

FIG. 1 is a schematic illustration of first and second objects, each having their own relative reference frame, and capable of navigation according to an embodiment of the invention.

FIG. 2 is a schematic view of the relative navigation system according to an embodiment of the invention.

FIG. 3 is a view of a grid projected into space from the grid generator for use with the navigation system of FIG. 2.

FIG. 4 is a view of several horizontally scanned lines that comprise the projected grid generated by the grid generator of FIG. 3.

FIG. 5 is a view of several vertically scanned lines that comprise the projected grid generated by the grid generator of FIG. 3.

FIG. 6 is a representation of one embodiment of the modulation of the scanned lines for use in the grid of FIG. 3.

FIG. 7 is a schematic view of the grid projected into space and the location of the detector modules within the grid.

FIG. 8 is a schematic view of a projected beam scanned over the detector module field of detection.

FIG. 9 is a schematic of unit vectors from the reference frame of the second object to each of the detector modules on the first object.

FIG. 10 is a schematic demonstrating the operation of the relative navigation system according to one embodiment of the invention.

FIG. 11 is a schematic view of another embodiment of a relative navigation system where one of the two objects is immobile.

FIG. 12 is a schematic view of yet another embodiment of a relative navigation system with multiple grid generator devices.

FIG. 13 is a schematic view of three detector modules within a projected grid of projected grid lines from a grid generator located on the first object.

FIG. 14 is a schematic view of the geometry for determining range between the first and second object.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is related to methods and apparatus for determining the range and relative attitude of two objects. This relative navigation system has various applications including automated vehicle navigation, mid-air refueling, space vehicle docking, and space satellite capture and servicing.

The invention will initially be described in the context of two docking objects 110 and 120, which are schematically illustrated in FIG. 1. The embodiment of FIG. 1 may be analogized to a mid-air refueling scenario, a space vehicle docking scenario, and a space satellite capture and servicing scenario. In all three of these scenarios, both objects are moving. However, either one of the objects 110 and 120 could be fixed or non-moving, with the other of the objects 110 and 120 moving, such as in an automated vehicle navigation, e.g. an airplane landing at an airport or a vehicle moving within a warehouse. It is also possible for the objects 110 and 120 to both be moving, and the relative navigation system may be used to maintain a desired attitude between the two objects without the two objects being docked, mated, coupled, etc., as the case may be. The docking scenario is selected because it is believed to provide the most detailed description.

The first object 110 has a first coordinate system 114 based on a first origin 112, within the body. Similarly, the second object 120 has a second coordinate system 124 based on a second origin 122. The location of the origins 112 and 122 may be at any desired location within the corresponding object and need not be coincident with a center of gravity or center of geometry of the object 112 and 122. However, in many cases, it is beneficial to locate the origin at either the center of gravity or the center of geometry. It is beneficial to select a known origin because then any location on the body can be determined relative to a known origin.

Each of the objects 110, 120 have corresponding surfaces 118, 128 respectively, which mate when the objects are docked. Therefore, the relative navigation between the objects 110, 120 requires that the objects be oriented facing each other and then brought into contact. In such a docking operation, it is useful to determine both the range and the time rate of change of the range between the first object 110 and the second object 120. The range is illustrated as the distance between the first origin 112 of the first object and the second origin 122 of the second object, shown as R₁. However, the range could be the distance between any other two points, which can easily be determined by relative reference to the distance between the origins 112, 122.

Additionally, the relative attitude and preferably the relative attitude rate between the first object 110 and the second 120 must be determined. The attitude is the pitch, yaw and roll of an object relative to a reference frame, which may be either of the reference frames 112, 122, for example. The relative attitude information is required to change the orientation of either the first object 110 or the second object 120, or both, such that the first front surface 118 of the first object 110 is correctly aligned with the second front surface 128 of the second object 120 as the two objects 110 and 120 approach each other for docking.

In one embodiment, the range and the relative attitude between the first object 110 and the second object 120 may be continuously determined over time, such as with time series data, with some periodicity. One or both of the objects 110, 120 may apply course corrections and/or attitude corrections by way of navigation of one or both of the first and second objects 110 and 120 to ensure proper mating with the correct orientation.

The manner in which the course correction and/or attitude corrections are made are not germane to the invention and will be dependent on the type of vehicle that the objects 110, 120 represent. Any suitable course corrector may be used. For example, where the object 110 is a space station moving in space and the object 120 is a space vehicle, such as a space shuttle, docking with the space station, the object 120 will have various rockets and thrusters for navigation, which may be used as necessary to adjust the attitude of the space vehicle to the space station for docking. In the case of an airplane landing on a runway, the engines and control surfaces of the airplane will provide the course/attitude correction during navigation.

FIG. 2 represents one embodiment of the present invention to determine the range and the relative attitude of the two objects (not shown here). The embodiment comprises a grid generator 140 and a detector array comprised of detector modules 150, 152, 154, and 156. The grid generator 140 projects a grid, such as a plurality of intersecting lines, into space within a field of transmission 141. For convenience, the field of transmission 141 originates from the second object at the origin 122 of the reference frame 124. However, the field of transmission 141 could easily originate from a known location spaced from the origin 122.

The detector array comprises multiple detector modules for detecting the grid generated by the grid generator 140. In this embodiment, four detector modules 150, 152, 154, and 156 are carried by the first object 110 at some known position 160, 162, 164, and 166 respectively, from the origin of the first object 114. As illustrated in FIG. 2, all of the detector modules are in a non-collinear distribution. In other embodiments, it is contemplated that at least one of the detector modules is positioned in a non-coplanar distribution to the other detector modules. The detector modules may also be both non-collinear and non-coplanar, which will provide the most accurate mathematical results.

The detector modules 150, 152, 154, and 156 further have a field of detection 151, 153, 155, and 157 respectively. For relative navigation between the objects 110, 120, it is presumed that the field of detection 151, 153, 155, and 157 of at least one of the multiple detector modules 150, 152, 154, and 156 lie within the field of transmission of the grid generator 140, enabling at least one of the detectors to “see” the grid. For best performance, the field of detection 151, 153, 155, and 157 of all of the detector modules 150, 152, 154, and 156 lie within the field of transmission of the grid generator 140.

FIG. 3 shows the grid as projected into space from the grid generator 140 with a field of transmission 141. As illustrated, the projected grid comprises intersecting lines. At some distance away from the grid generator 140, these intersecting lines are observed as a grid in space, with the size of the grid increasing away from the grid generator 140.

For description purposes, the grid generator can be thought of as projecting intersecting lines substantially in the y direction of the coordinate system. If one were to observe the projection of intersecting lines in the x-z plane at some distance R₂ away from the grid generator 140, one would observe at first grid 170. If one were to observe the same projection of intersecting lines at a distance R₃, which is greater than the first distance R₂ in the x-z plane, one would observe a second grid 190, which appears relatively larger than the grid 170.

The first grid 170 at distance R₂ away from the grid generator 140 is spatially bound in the horizontal direction by a first vertical line 172 and a second vertical line 173. There exists a plurality of vertical lines spatially and temporally generated in between the first vertical line 172 and the second vertical line 173. The first grid 170 at a distance R₂ away from the grid generator 140 is spatially bound in the vertical direction by a first horizontal line 174 and a second horizontal line 175. There exists a plurality of horizontal lines spatially and temporally between the first horizontal line 174 and the second horizontal line 175.

The distance R₂ can be any distance between the grid and the grid generator. For convenience, the distance is determined between a point 176 on the first grid 170 and the grid generator as shown.

The vertical and horizontal lines may be formed in any suitable manner by the grid generator 140. For example, all of the lines may be formed sequentially or all at once. Either one of the vertical lines or horizontal lines may be formed before the other. The grid generator may alternate between vertical and horizontal lines. When the grid generator 140 uses a scanning laser to form the grid, the laser will sequentially form all of one of the vertical and horizontal lines, followed by the sequential forming of the other of the vertical and horizontal lines. The rate at which the lines are sequentially formed may be so fast that for practical purposes, it is as if all of the grid lines were simultaneously formed.

The second grid 190 at distance R₃ away from the grid generator 140 is for all practical purposes the same as the first grid 170, but at further distance from the grid generator 140 than the first grid 170. The grid 190 is spatially bound in the horizontal direction by a first vertical line 192 of the second grid 190 and a second vertical line 193 of the second grid 190. There exists a plurality of vertical lines spatially and temporally generated in between the first vertical line 192 of the second grid and the second vertical line 193 of the second grid. The second grid 190 at a distance R₃ away from the grid generator 140 is spatially bound in the vertical direction by a first horizontal line 194 of the second grid 190 and a second horizontal line 195 of the second grid 190. There exists a plurality of horizontal lines spatially and temporally between the first horizontal line 194 of the second grid and the second horizontal line 195 of the second grid. A point 196 on the second grid 190 is shown.

The similarity of the grids 170 and 190 becomes apparent in the case of projected grid lines, where the grid 190 is formed by the same lines forming the grid 170, except the grid 190 is observed at a further distance from grid generator 140, making the grid 190 appear larger than the grid 170. In this sense, the grid 190 is the appearance of the grid lines generated by the grid generator at the distance R₃ whereas the grid 170 is the appearance of the grid lines at the distance R₂. Thus, as object 110 approaches object 120, the grid seen by the object becomes smaller.

The grids 170 and 190 may be of any number of lines. As illustrated, they are comprised of ten vertical lines by ten horizontal lines. A grid comprised of a greater number of intersecting lines may result in improved detection angular resolution for a fixed field of transmission 141 and distance from the detector 140 than a grid comprised of a fewer number of intersecting lines. The grids 170 and 190 are depicted as a square shape, but this is not a requirement for the methods and apparatus of this invention. The grid can be any shape including rectangular, oval, or circular. Furthermore, the intersecting lines of the grids 170 and 190 are depicted as orthogonal; however, this is not a requirement for the methods and apparatus of the present invention. The angles between the intersecting lines may be right angles, acute angles, or obtuse angles in different parts of the grid.

Although, examples shown use Cartesian coordinates, any appropriate coordinate system may be used including polar, cylindrical, or spherical coordinate systems for both grid generation and for grid detection. For example, to form a grid amenable to polar coordinate representation, a series of concentric circles and lines radiating out from the center of those circles may be projected by the grid generator into space.

The radiation source for the plurality of projected lines may be a coherent or incoherent radiation source. For example, when the radiation source is a coherent source, it may be a solid state laser that emits radiation at a wavelength in the near-UV range. Additionally, the radiation intensity may be selected, or attenuated by use of an optical filter, to reduce the risk of eye damage.

The grid of intersecting projected lines may be generated by raster scanning each of the lines or by projecting and scanning an elongated radiation beam. FIGS. 4 and 5 depict one embodiment of how the grid generator 140 generates the vertical and horizontal lines. In this embodiment, the grid generator 140 raster scans horizontal line 200 in the direction indicated by arrow 206. The grid generator then steps to the next line location and raster scans the subsequent horizontal line 202, again in the direction of 206. This process is repeated for the next line 204 and all subsequent lines until all the horizontal lines are scanned. The vertical lines are scanned in a similar manner with a first vertical line 210 raster scanned in the direction indicated by arrow 216, followed by stepping and repeating the process for the next vertical lines 212 and 214 and all subsequent vertical lines. Additional methods and apparatus for generating the intersecting lines are described in detail in US patent publication 2008/0067290, the contents of which are incorporated herein by reference in its entirety.

A grid word may be encoded at one or more locations of the grid. By grid word, it is meant that the structure or characteristic of the grid provides data or information that may be read or detected by the detector modules. In one embodiment, the projected lines comprising the series of projected intersecting lines are further encoded with a different grid word in different regions of the grid to indicate regions within the grid of intersecting lines. One manner of encoding of the grid word is by modulating the beam in the case of a laser being used to form the grid. The modulation is achieved by changing the intensity of the beam and/or blocking the beam with some periodicity.

FIG. 6 illustrates an amplitude modulation scheme to modulate and encode scanned lines with a grid word. The amplitude modulation scheme may be applied to a single line or to multiple lines forming the grid. In this embodiment, the period of each bit is time T_(s), with a logical ‘1’ bit represented by a beam intensity of A and a logical ‘0’ bit represented by a beam intensity of 0. This embodiment further shows a grid word comprised of 18 bits transmitted over a time of 18 T_(s). Some of these bits may be data bits for encoding the location on the grid and other bits might be grid word start or stop indicators or error checking bits. Thus, as the detector module monitors the amplitude of the line over time, a processor or circuitry associated with the detector may be used to determine the word contained in that location of the grid.

Each of the intersecting projected lines could be encoded differently or a grouping of intersecting lines could be encoded similarly. Additionally, the grid word could be comprised of any number of bits, including any number of start or stop bits, data bits, or error checking, correction or parity bits. The data bits may encode each of the vertical and horizontal lines with a unique sequence of bits. Upon detection of these bits by the detector module and processing by the processor, microcontroller, or other circuitry, the location within the grid can be determined. Any number of known modulation methods could be used for encoding the grid words on to the plurality of intersecting projecting lines, including but not limited to, amplitude modulation (AM), frequency modulation (FM), quadrature amplitude modulation (QAM), or combinations thereof.

In another embodiment, the modulated projected lines may be used as a communication link from the object with the grid generator to the object with the detector array. This link can be used to send messages other than just information on locations within the grid. For example, the modulated grid lines may be used to send messages such as conveying where in the grid the first object may want the second object to park, or to wait for further commands. The link can be used to send limited amounts of information by time-multiplexing the information in the grid word. This generalizes the grid as a data link.

FIG. 7 illustrates a view of the grid of intersecting projected lines 170 from the normal direction bound by vertical lines 172 and 173 and horizontal lines 174 and 175 with the field of view 151, 153, 155, and 157 of each of the detector modules 150, 152, 154, and 156 (as shown in FIG. 2). In this embodiment each of the vertical and horizontal lines are encoded such that each of the regions within the grid, 1 through 100, can be identified. The four detector modules are in a non-co-planer configuration with a resulting non-co-planer configuration of the field of view 151, 153, 155, and 157 of each of the detector modules. The circles in FIG. 7 illustrating the field of view are of different sizes because the non-coplanar spacing of the detectors will yield a different area, which is defined as the intersection of the field of view with the grid.

Each detector module produces an output signal based upon the line or lines that pass through the field of view of the detectors. The field of view may be controlled by selecting the aperture for each detector. It is possible for each detector to have a different field of view. When a word is embedded in the grid, the field of view of the detector must at least be large enough such that a projected line is within that field of view long enough to detect the transmission of a complete grid word associated with the line intersecting the detector module. Thus, the field of view of the detector may be several times the size required to detect a complete grid word of a line passing through the field of view of the detector, to ensure reliable detection.

The output signals of each of the detectors are then demodulated and processed to determine the location of the detector within the projected grid of intersecting lines. The demodulation may be conducted by a processor, field programmable gate array (FPGA), application specific integrated circuit (ASIC) or similar computer coupled to the detectors.

The embodiment disclosed herein measures range by counting the number of bit transitions with periodicity T_(S) of the grid word detected at each detector module. Alternatively, one could count the number of lines seen by one or more of the detector modules. However, this approach is limited to the angle of view of the detectors whereas by looking at the bit transitions, it is possible to identify the spot on the grid seen by the detector, which works better when the objects are close enough that each detector can only see one line. The method also takes into account that the number of bit transitions detected will also be affected by the relative attitude of the detector module to the grid generator.

FIG. 8 illustrates one of the detectors with a field of detection and the portion of the grid that falls within the field of detection. As can be seen, the grid generator scans the projected line at an angular rate of ω_(s). The angle subtended in one cycle time T_(s) 222 is ω_(s)T_(s). The number of bit transitions detected by the detector module is given by the following relationship:

$N_{S} = \frac{{Tan}^{- 1}\left( \frac{D_{A}}{R_{A}} \right)}{\omega_{S}T_{S}}$

Where D_(A) is the dimension of the field of detection 151 of detector module 150.

N_(S) is the number of bit transitions detected by the detector module.

R_(A) is the distance from the grid generator 140 to the detector module.

Solving for R_(A) gives the following relationship:

$R_{A} = \frac{D_{A}}{{Tan}\left( {N_{S}\omega_{S}T_{S}} \right)}$

The position vector to each of the detectors is given by:

$R_{i} = {\begin{bmatrix} u_{x}^{d} \\ u_{y}^{d} \\ u_{z}^{d} \end{bmatrix}R_{A}}$

Where i indexes each detector and u^(d) _(x), u^(d) _(y), and u^(d) _(z) are the x, y, and z components of the unit vectors in the reference frame 124 of the second object 120 in the direction of each of the detectors as shown in FIG. 9. Each of the vectors 132, 134, 136, and 138 from the origin 122 of the reference frame 124 of the second object 120 is shown. The x, y, and z components of each of these unit vectors for each of the detectors is represented by u^(d) _(x), u^(d) _(y), and u^(d) _(z), respectively and are derived from grid angle information.

The position vectors from all the detector modules are processed using an Absolute Orientation algorithm which determines the relative attitude direction cosine matrix between the coordinate frame defined by the grid generator 140 on the second object 120 and the coordinate frame on the chase vehicle in which the vectors to the detector positions is defined. The distance from the second object to each detector i on the first object is given by the equation: R _(i) =C _(B) ^(R) D _(i) +r _(i)

Where C^(R) _(B) is the relative attitude direction cosine matrix;

D_(i) is the distance from the origin 112 of the first object 110 to each detector module i on the first object 110, and is a fixed and measurable quantity that is the scalar length of vectors 160, 162, 164, and 166 between the origin 112 of the first object and each of the detectors as shown in FIG. 2; and

r_(i) is the distance between grid generator 140 and origin 122 of the coordinate frame 124 and the origin 112 of the coordinate frame 114 of the first object 110.

The method solves for the relative attitude direction cosine matrix, C^(R) _(B) given the grid generator 140 measurements, R_(i) and the fixed distances, D_(i). A minimum of three and preferably four measurement pairs {R, D}_(i) are required for the solution. In one embodiment, the Horn Algorithm is used to solve the relative attitude direction cosine matrix; however, any other known methods may be used for this solution.

Multiple determinations over time of the direction cosine matrix may provide the basis for determining the rate of change in the attitude between the first object 110 and the second object 120. At least two direction cosine matrices must be determined to calculate a rate of change. A sampling rate for determining the position data and the corresponding direction cosine matrix will be selected based on the anticipated environment and rate of change such that the resulting attitude rate change will provide useful data.

In one embodiment the attitude rate can be determined from back differencing the relative attitude direction cosine matrix. A time series of attitude rates can be determined from the time series of relative attitude direction cosine matrices. The particular method for conducting the back differencing is not germane to the invention. Any suitable method may be used to obtain the attitude rate.

A Kalman Filter may be used to estimate the relative position of the origin of the first object 112 to the origin of the second object 122, as well as the relative velocity from multiple position observations as disclosed above. Each orthogonal element of the position measurement may be processed with a multi-state Kalman filter to estimate the relative position, velocity and possibly other parameters such as acceleration between the first object 110 and the second object 120. Methods other than multi-state Kalman filter may be used to make these calculations. In one embodiment, the algorithms described are executed in a processing unit 142 such as a microprocessor or a microcontroller as shown in FIG. 10.

It may be advantageous in certain applications and system designs to have a greater field of detection of the detector module (D_(A)). In one embodiment, the detection module may be comprised of a detector of the radiation emitted by the grid generator 140 and one or more optical elements to enhance the field of detection of the detector module. As an example the detector may be a silicon based photodetector. The one or more optical elements of the detector module may comprise mirrors, lenses, or combinations thereof. In another embodiment, the detector module does not comprise any optical elements.

The relative range, velocity, attitude, and rate of attitude determined from the apparatus and methods described herein are used for relative navigation of one or both of the objects 110 and 120. The data may be used for course corrections for purposes of one object approaching the other object, one object approaching the other object at a preferred velocity, one object approaching the other object at a preferred velocity and attitude, for the objects to avoid each other or to maintain a required distance or orientation between the objects.

FIG. 10 shows an example of the two objects 110 and 120, a chase vehicle and a target vehicle, orienting and docking with each other with the front face 118 of the first object 110 approaching the front face 128 of the second object 120 using the apparatus and following the methods disclosed. The two objects 110 and 120 are initially non-oriented with each other and at a distance as indicated by position A of the first object 110. The grid generator 140 on the second object 120 continuously projects a grid of intersecting lines that is detected by the detector modules 150, 152, 154, and 156 on the first object 110. The outputs of the detectors are communicated to the processing unit 142 by the detector module communications path 144. The outputs of each of the detector modules 150, 152, 154, and 156 are demodulated and processed in the processing unit 142 to determine the range and relative attitude between the two objects 110 and 120 using the algorithms and methods disclosed above. Based upon the relative attitude and range determined, the processing unit may initiate a course corrector, which is illustrated as the firing of one or more thrusters 146, to change the orientation and position of the first object 110 as shown in position B at some time after the object 110 was at position A. The processing unit communicates with the thrusters via a thruster communication path 148. This process is then repeated, with the detector modules 150, 152, 154, and 156 detecting the grid of intersecting lines projected by the grid generator 140 located on the second object 120, with the outputs of the detector modules processed by the processor unit 142 to determine the relative attitude and range between the two objects 110 and 120, and then using this information to initiate course corrections by firing one or more thrusters 146 on the first object 110 to preferentially change the position and orientation of the first object 110. This process is repeated until a final position and orientation of the first object 110 that allows docking with the second object 120 is achieved as shown in position D.

As illustrated in this example, there are two intermittent maneuvering operations shown, however, there may be any number of maneuvering operations. The number of maneuvering operations may depend on the sampling period of the measurements, initial distance between the two objects 110 and 120, or the initial relative attitude of the two objects 110 and 120. The grid generator 140 on the second object 120 and the detectors 150, 152, 154, and 156 and processing unit 142 on the first object 110 may be located on their respective objects to not interfere with the maneuvering or docking process and not incur damage during such operations. The processing unit 142 may comprise one or more processors, microcontrollers, memory devices, digital signal processors, field programmable gate arrays, integrated circuits, discrete electronic components, discrete passive components, circuit boards, electrical connectors, power supplies, or combinations thereof. The detector module communications path 144 and the thruster communications path 148 may be either a protocol or non-protocol based communications path, and may employ any known medium such as twisted pair or coaxial cable, or alternatively communicate wirelessly by any number of known protocols and standards such as ZigBee or Bluetooth.

The aforementioned methodology can be used in substantially the same manner for other applications. For example, in an automated airplane landing on a runway, the processing unit may control airfoils and other control surfaces of the aircraft based on the time series range and attitude data collected, rather than thrusters as in the space docking application.

For illustrative purposes, the relative navigation of two objects is considered and disclosed, but the methods and apparatus disclosed may be used for the relative navigation of multiple objects. It is also obvious that if course corrections are carried out on the object carrying the grid generator (second object 120) rather than the object carrying the array of detector modules (first object 110), or if both objects make course corrections, then the first object must communicate the range and relative attitude time series data to the second object. This communication between the two objects may transpire over a wireless communications channel such as radio frequency communication with the use of a variety of communications protocols on either a unidirectional or bi-directional channel. Alternatively, the communications between the two objects may transpire indirectly via a third party such as a communications satellite with the use of a variety of communications protocols and methods.

The methods and apparatus disclosed produce range and attitude data from a single grid generator on one object and a single array of detector modules on the other object. Two separate hardware setups are not required for the range and the attitude. This has the advantage of smaller form factors and weight of a complete navigation system, both of which are important in space and aerial applications. In one embodiment, all the components of the grid generator are packaged as a single unit. Additionally, the detector module array may have redundant detectors, such that high reliability can be achieved even if one or more detector modules fail during operation.

Illustrated in FIG. 11 is another embodiment of the present invention, wherein the second object 320 is not mobile and is fixed in location with a grid generator 340 attached thereon. This object 320 could, for example, be a wall or ceiling of a building. The first object 310 is a moving object with a front side 318, a rear side 316, a coordinate frame 314 with an origin 312, and with one or more detector modules attached thereon. In one embodiment, there are four detector modules 350, 352, 354, and 356. There is a field of transmission 341 of the radiation from the grid generator 340. This radiation is radiated in a manner to generate a plurality of projected intersecting lines. These projected lines are either elongated beam lines scanned in one direction or point beams raster scanned in substantially both the horizontal and vertical directions. In one embodiment the plurality of intersecting lines are further modulated to encode them distinctly from other of the plurality of intersecting lines. The detector modules 350, 352, 354, and 356 on the first object detect the position on the projected grid generated by the grid generator 340. The output of the detector modules are processed with algorithms to generate one or more of relative range, velocity, attitude and rate of attitude between the first object 310 and the second object 320 in a repeating time series manner. These measurements are then used for real time course correction of object 310 to achieve proper range and orientation of the first object 310 to the second object 320. It should also be noted that the first object may be moving in a two dimensional plane such as a car on a flat surface or in a three dimensional plane such as an aerial application.

FIG. 12 is another embodiment of the present invention, where there is a first object 410, with a front surface 418, a rear surface 416, with a reference coordinate system 414 with an origin 412 and several detector modules 450, 452, 454, and 456 attached thereon. The second object 420 in this embodiment has a front surface 428 and a rear surface 426 and has more than one grid generator attached thereon. Grid generators 440, 442, 444, and 446 have a field of transmission of 441, 443, 445, and 447 respectively. Several grid generators may be desirable in certain applications to enable navigation over a wider range of relative positions. In a single grid generator case, if none of the detector modules of first object are not within the projection of the grid generator then it might be difficult to navigate the first object to bring it within the field of projection of the grid generator. With multiple grid generators, the relative range, velocity, attitude and attitude rate may be determined in a greater volume of space surrounding the second object 420. When using multiple grid generators, an additional complexity of differentiating between the transmissions of the various grid generators must be addressed. In one embodiment, each of the grid generators encode the plurality of intersecting lines uniquely from the other grid generators, for example with a unique grid word for all lines, regardless of the grid generator that produced the line. In another embodiment, each grid generator may emit radiation of a distinguishably different wavelength from the other grid generators and the detector modules on the first object will be able to ascertain the grid generator by detecting the wavelength of the radiation. In this later embodiment, each detector module 450, 452, 454, and 456 may comprise more than one detector sensitive to the various wavelengths emitted by the several grid generators 440, 442, 444, and 446 located on the second object. Alternatively the detector modules may comprise one or more optical filters to detect different radiative wavelengths from more than one grid generator.

FIGS. 13 and 14 illustrate another embodiment for finding the range between the first and second objects. FIG. 13 is a schematic view of three detector modules 551, 553, and 555 within a projected grid of projected grid lines 570 from a grid generator 540, which may be located on the origin point or at a known relationship to the origin of either the first or second object as described in the first embodiment. The grid of projected grid lines 570 is bound vertically by a first vertical grid line 572 and a second vertical grid line 573 and is bound horizontally by a first horizontal grid line 574 and a second horizontal grid line 575. The three detector modules 551, 553, and 555 are located in a predetermined triangular relationship on the other of the first and second objects as described in the first embodiment, with each of the detector modules defining each of the three vertices of the triangle, where there are three unique pairs of vertices. Detector module 551 is spaced from detector module 553, 553 from 555, and 551 from 555, by predetermined distances a, b, and c, respectively. Each of the detector modules 551, 553, and 555 can detect grid lines passing through its field of view and the corresponding modulated grid words. The location within the grid of each of the detector modules 551, 553, and 555 forming the vertices of the triangle is determined from the grid words detected at each of the detector modules.

FIG. 14 is a schematic view of the geometry for determining range between the first and second object from FIG. 13, with the grid of projected grid lines 570 removed for greater clarity. The distance between the grid generator 540 on the first object and the three detector modules 551, 553, and 555 are represented by d₁, d₂, and d₃, respectively. Unit vectors in the direction from the grid generator 540 to each of the detector modules 551, 553, and 555, are represented by j₁, j₂, and j₃. The position within the grid of projected grid lines 570 of the detector modules 551, 553, and 555 can be transformed into the three unit vectors, j₁, j₂, and j₃. The angles subtended between each of the three unit vectors can be determined using the following equations: cos(α)=j ₁ ·j ₂ cos(β)=j ₂ ·j ₃ cos(γ)=j ₃ ·j ₁

Where α is the angle subtended by unit vectors j₁ and j₂.

β is the angle subtended by the unit vectors j₂ and j₃.

γ is the angle subtended by the unit vectors j₁ and j₃.

The function · represents the dot product between two vectors, resulting in a scalar quantity.

Using the Law of Cosines, a mathematical relationship between the distances d₁, d₂, and d₃, the angles α, β, and γ, and the predetermined distances a, b, and c can be shown as the following equations: d ₂ ² +d ₃ ²−2d ₂ d ₃ cos(β)=b ² d ₁ ² +d ₃ ²−2d ₁ d ₃ cos(γ)=c ² d ₂ ² +d ₁ ²−2d ₂ d ₁ cos(α)=a ²

In this set of three equations, the values of α, β, γ, a, b, and c are known and the values for d₁, d₂, and d₃ need to be determined, which can be done using any known technique. It is contemplated that this set of three equations can be solved using the Grunert algorithm as disclosed in R. M. Haralick et al., “Review and Analysis of Solutions of the Three Point Perspective Pose Estimation Problem,” International Journal of Computer Vision, 13, 3, pp. 331-356 (1994), and is incorporated herein by reference. By using the Grunert algorithm, the values of d₁, d₂, and d₃ can be derived. The d₁, d₂, and d₃ values can be further manipulated, such as averaged, to determine a single range between the first and second objects.

The Grunert algorithm will likely be solved in a processing unit such as a microprocessor, FPGA, or ASIC on the second object. As an alternative to the Grunert algorithm, any number of other methods may be used to solve the geometric problem of FIG. 14, including but not limited to, Finsterwadler Solution, Merritt Solution, Fischler and Bolles Solution, Grafarend, Lohse, and Schaffrim Solution, or Linnainmaa, Harwood, and Davis Solution.

Range information determined by the method describe above may be used to navigate or effect a change in the range between the two objects by moving one or both of the objects. The range information may be input to a navigation system that may control one or more thrusters or other means to move one of the first and second objects. In some applications, one of the objects may not be moveable and in other applications, both objects may be moveable. In such an active navigation application, the method disclosed for determining the range may be executed repeatedly at a frequency appropriate to make necessary changes to the range between the two objects.

As an alternative to three detector modules there may be four or more detector modules. Additional detector modules may provide for additional redundancy, in case one or more detectors fall outside of the grid of projected grid lines 570. Additional detector modules that detect the grid of projected grid lines 570 could provide for additional triangles between two or more sets of three detector modules, resulting in additional error checking and additional robustness in range measurement and calculation.

With current grid generating systems and detectors, the error in the determined range from this method may be on the order of 1 inch or less at a range of 100 feet. The error in the determined range may depend on the distances between the detector modules, where an increased distance between the detector modules may result in reduced error in the range determination. Such consideration may play a part in determining where on an object, such as an aircraft, to place detector modules. The determined range may also be susceptible to geometric errors if the triangle defined by the three detector modules is highly oblique to the grid. The range finding methods disclosed herein may be combined with the attitude information to estimate this error.

The range measurement using this embodiment is different from the first embodiment described in conjunction with FIG. 8 in that the number of bit transitions, N_(s), in the grid word of the grid line passing through the field of view of the detector module does not have to be determined. Not having to determine N_(s) is advantageous because, that number may have significant errors associated with it based on several factors, including whether the detector module is positioned normal to the grid of projected grid lines 570 and the level of noise in the modulated grid lines. As there may be relatively few bit transitions, N_(s), within the field of view of a detector module, miscounting the bit transitions by even a few bit transitions may result in large errors in the range determination for methods that rely on determining the number of bit transitions, N_(s). On the other hand, if the range finding method relies on finding the position of three or more detector modules within the grid of projected grid lines 570, as is disclosed in this second range finding embodiment, even if a few bit transitions are not detected, the detector may be able to detect a complete grid word to indicate its position within the grid of projected grid lines 570. In some applications, it may further be advantageous to combine both the first (based on determining bit transitions) and the second (based on the location of three or more detector modules within the grid) methods for determining range between the two objects.

This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims. 

1. A method of determining range between first and second objects with relative movement, the method comprising: projecting into space from the first object a grid comprised of a plurality of grid lines from a first origin point on the first object; modulating each grid line to carry a grid word comprised of a number of modulated bits to identify each grid line within the grid by the modulated grid word; detecting the grid lines and the corresponding grid words from at least three locations having a predetermined triangular relationship on the second object, with each location defining a vertex of the triangle, which define three unique pairs of vertices; determining the location within the grid of the three vertices based on the grid word detected at each of the at least three locations; for each unique pair of vertices, determining an angle subtended by a pair of unit vectors extending from the origin based on the location within the grid of each of the vertices, with each unit vector passing through one of the vertices of the unique pair, to form a set of three subtended angles; determining the range between the first and second objects based on the set of subtended angles.
 2. The method of determining range of claim 1, further comprising adjusting the range of at least one of the first and second objects based on the determined range.
 3. The method of determining range of claim 1, wherein at least two of the plurality of grid lines intersect.
 4. The method of determining range of claim 3, wherein the projecting of the grid lines comprises first projecting a first set of parallel and spaced grid lines followed by projecting a second set of parallel and spaced grid lines, orthogonal to the first set.
 5. The method of determining range of claim 3, wherein the projecting of the grid lines comprises projecting a series of concentric circles having a common center and lines radiating out from the center and intersecting the concentric circles.
 6. The method of determining range of claim 1, wherein at least one of the first and second objects is a moving object and the other is a non-moving object.
 7. The method of determining range of claim 1, wherein both of the first and second objects are moving objects.
 8. The method of determining range of claim 1, wherein the range is determined repeatedly over time.
 9. The method of determining range of claim 1, wherein a range is determined between the first object and each of the three vertices.
 10. The method of determining range of claim 9, wherein the range between the first object and each of the vertices is determined by applying a mathematical relationship between the range between the first object and each of the vertices to the distance between a pair of vertices and the angle subtended by vectors from the first object that pass through that pair of vertices.
 11. The method of determining range of claim 10, wherein the range between the first object and each of the vertices is further determined by applying the Grunert algorithm.
 12. The method of determining range of claim 10, wherein the range between the first and second objects is determined by averaging each of the ranges between the first object and each of the vertices. 